Hydraulic circuit for hybrid electric transmission

ABSTRACT

A hydraulic circuit for a vehicle powertrain includes a first line for carrying fluid to a torque converter, a second line for carrying fluid from the torque converter, a third line for carrying fluid to a balance dam and an electric motor, and a fourth line for supplying actuating pressure to a clutch, said lines being coaxial.

This application is a continuation-in-part of pending U.S. application Ser. No. 13/271,044, filed Oct. 11, 2011.

TECHNICAL FIELD

This invention relates to the powertrain of hybrid electric vehicles, particularly to a hydraulic circuit that supplies fluid to a torque converter, balance dam and motor and actuating pressure to a clutch.

BACKGROUND

Hybrid electric vehicles (HEVs) have both an internal combustion engine and an electric motor which can alternately or in combination be used to propel the vehicle. A variety of different drive trains are used in hybrid vehicles. The present application relates to a parallel configuration in which the engine is connected to the motor by a disconnect clutch with the motor driving the torque converter input of an automatic hydraulic transmission. The hydraulic transmission has an output which is connected to a differential coupled to the two driven wheels of the vehicle. This parallel hybrid electric vehicle drive chain power flow arrangement is known in the art.

A problem facing HEV designers is how to cool the disconnect clutch and the rotor and stator portions of the electric motor. Various air and liquid based cooling systems have been proposed; however, most systems are costly and pose packaging problems when trying to convert a non-hybrid vehicle to a hybrid operation. A need exists to package the disconnect clutch, motor, torque converter and automatic transmission in a compact manner so that a conventional vehicle can be reconfigured as a hybrid at a relatively low cost and with little or no vehicle body modifications.

SUMMARY

A hydraulic circuit for a vehicle powertrain includes a first line for carrying fluid to a torque converter, a second line for carrying fluid from the torque converter, a third line for carrying fluid to a balance dam and an electric motor, and a fourth line for supplying actuating pressure to a clutch, said lines being coaxial.

The present invention relates to a novel hybrid electric vehicle as well as a number of novel components and subcomponents specifically adapted to reorient the disconnect clutch and the electric motor within the wet side of the automatic transmission. This is done without changing the conventional power flow in which the engine, disconnect clutch, motor, torque converter, transmission are connected in series.

Rather than connect the torque converter directly to the engine as is typically done in a non-hybrid vehicle, a drive shell is provided which connects the engine to the input side of the disconnect clutch which is has been relocated into the automatic transmission housing. The drive shell forms an annular cavity of sufficient size to contain the torque converter freely therein. The motor is also located in the automatic transmission wet zone preferably circumaxially surrounding the disconnect clutch. The rotor of the motor is connected to the disconnect clutch output. The disconnect clutch output and the rotor are both coupled to the rotor shaft which is connected to input turbine of the torque converter. The torque converter stator and the output turbine are connected to a tubular stator shaft and a transmission input shaft respectively. The transmission input shaft, the stator shaft, the rotor shaft and the disconnect clutch hub are all concentric with one another and accessible through an annular opening in the front side of the automatic transmission housing.

The torque converter and the drive shell are removably mountable on the front of the transmission housing similar to a conventional torque converter. Rather than attaching the torque converter to the engine mounting plate, a drive shell is attached to the mounting plate. The torque converter is free to rotate relative to the drive shell within the drive shell cavity, resulting in a compact and axially short motor/transmission assembly. By locating the disconnect clutch and motor coaxially in the front portion of the wet zone of the automatic transmission, the transmission hydraulic fluid pump, associated pump and plumbing system can cool the disconnect clutch and the rotor and stator portions of the electric motor with relatively little increase in axial length.

The torque converter, while generally similar to a conventional torque converter, is uniquely adapted in order to practice the invention. Since the torque converter is not attached to the engine mounting plate, no mounting studs are provided on the shell of the torque converter. Rather, a central axially bearing member is provided which cooperates with an engine mounting plate provided with a corresponding bearing member in order to radially support the torque converter and limit axially movement in the forward direction. Within the torque converter is a rearward facing thrust bearing member which cooperates with the free end of the transmission input shaft to limit the axial movement of the torque converter in the rearward direction.

The transmission housing is preferably also uniquely adapted in order to practice the present invention. The transmission housing includes a wet housing which partially defines an enclosed wet zone and a torque converter housing, adapted to be affixed to the wet housing on one side and to the engine block on the other. The torque converter housing has a rear wall which forms a boundary between the wet cavity and the dry cavity in which the torque converter and drive shell are oriented. The rear wall defines an annular bore which cooperates with the disconnect clutch input hub to support the input hub and the rotor shaft along with the associated rotor portion of the motor and the disconnect clutch output hub.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic illustration of a hybrid electric vehicle having a parallel-flow design;

FIG. 2 is a simplified schematic illustration of the disconnect clutch and motor reoriented in the present invention;

FIG. 3 is a simplified cross-sectional view of an automatic motor/transmission assembly of the present invention;

FIG. 4 a is a more detailed cross-sectional side elevation view of an automatic motor/transmission assembly of the present invention;

FIG. 4 b is a stick diagram of the motor/transmission assembly of FIG. 4 a;

FIG. 4 c is a clutch application schedule for each of the six forward gears and reverse;

FIG. 5 is an enlarged view of the cross-section of the torque converter in its cooperation with the disconnect clutch and motor;

FIG. 6 is an enlarged view of the disconnect clutch and electric motor;

FIG. 7 is an enlarged view of the engine output on the mounting plate torque converter and the transmission input shaft showing their axial orientation;

FIG. 8 is a perspective view of a mounting plate used to practice the present invention;

FIG. 9 is a perspective view of a torque converter used to practice the present invention;

FIG. 10 is a perspective view of a drive shell;

FIG. 11 is a view of an alternative embodiment of the drive shell with a torque inverter entrapped therein;

FIG. 12 is side cross-sectional view of the portion of the vehicle powertrain located above the central axis;

FIG. 13 is top view of a terminal block assembly;

FIG. 14 is side cross-sectional view of a portion of the vehicle powertrain located below the central axis;

FIG. 15 is side cross-sectional view above the central axis of vehicle powertrain showing a torsion damper located between the engine and torque converter.

DETAILED DESCRIPTION

FIG. 1 illustrates a hybrid electric vehicle 10 schematically shown with a parallel type hybrid electric drive train. The hybrid electric vehicle is provided with an engine 12 having a rotary output which is connected to a disconnect clutch 14 which drives an electric motor 16. The output of the electric motor is connected to the input of torque converter 18, the output of which is connected to the input shaft of automatic transmission 20. In a conventional manner, the automatic transmission is connected to the driven wheels, 22, 22′ by a differential 24. In the schematic illustration, hybrid electric vehicle 10 is provided with a pair of non-driven wheels, however, alternatively, a transfer case and a second differential can be utilized in order to positively drive all of the vehicle's wheels. The engine, disconnect clutch, motor, torque converter and the automatic transmission are connected sequentially in series, as illustrated in FIG. 1.

Motor/transmission assembly 26, in hybrid electric vehicle 10′, schematically illustrated in FIG. 2, repackages the drive components while maintaining the same power flow, as shown in FIG. 1. Engine 12 is mechanically connected to the input side above disconnect clutch 14 via a drive shell 28 which forms an annular chamber sufficiently large to extend about torque converter 18. The output of disconnect clutch 14 is connected to electric motor 16 which, in turn, is connected to the Impeller “I” of torque converter 18. The use of the drive shell 28 enables the disconnect clutch and motor to be positioned within the wet side of the automatic transmission housing. Turbine “T” is attached to the output of torque converter 18 which is connected to the input shaft of the automatic transmission in a conventional manner. The invention can be practiced with a wide variety of automatic transmissions. The preferred embodiment of the transmissions described herein is a six-speed, three planetary gear set, five clutch design; alternative transmission structures having fewer or greater speeds and different mechanical configurations can likewise be benefited from the present invention.

A more detailed, yet quite simplified illustration of the motor/transmission assembly 26 is shown in FIG. 3. The engine is provided with a crank shaft output flange 30 which is bolted to mounting plate 32 in a conventional manner. The mounting plate 32, rather than attaching to the shell of the torque converter, is affixed to the drive shell 28 which has sufficient diameter to encircle the torque converter and connect to the input hub 34 of disconnect clutch 14. The output of the disconnect clutch is affixed to the rotor “R” portion of motor 16 and in turn, is connected to rotor shaft 36. The rotor shaft 36 is coaxially nested within the disconnect clutch input hub 34 and extends to an annular opening in the wall portion of the transmission housing defining the wet zone of the transmission. Rotor shaft 36 is connected to the impeller “I” of torque converter 18, which in turn drives turbine T connected to transmission input shaft 38. Coaxially spaced between the inside diameter of rotor shaft 36 and the periphery of the transmission input shaft 38 is a stator shaft 40 which is fixed relative to the transmission housing and supports stator element S located within torque converter 18.

Preferably, the case of the motor/transmission assembly is made up of a wet housing 42 which partially defines the enclosed wet zone cavity, and a torque converter housing 44 which is adapted to be affixed to the wet housing 42 and to the engine block 46. The torque converter housing 44 is preferably provided with rear wall 48 having an annular axial opening 50 on the transmission centerline. Rear wall 48 forms a physical boundary between the wet zone cavity and a dry cavity in the transmission housing. The torque converter 18 and drive shell 28 are located in the dry zone as shown. Rear wall 48 cooperates with disconnect clutch input hub 34 which in turn supports motor rotor shaft 36 and the associated rotor portion R of motor 16.

The motor/transmission assembly is provided with pump P for hydraulic fluid oriented within the wet zone of the transmission housing and driven by the rotor shaft 36. Pump P provides pressurized hydraulic fluid to operate the clutches and brakes within the transmission drive train as well as operating the disconnect clutch and provides cooling for the clutches and motor 16. Similarly, the disconnect clutch and motor share a common sump 52 for transmission fluid as well as a common pump screen 54. Automatic transmission 20 is provided with an output shaft 56. FIG. 4 a is a cross-sectional side elevational view of the motor/transmission assembly 26. Once again, the present invention can be utilized with a number of different transmission gear train configurations and is not limited to the disclosed six-speed, three planetary gear set transmission.

The preferred embodiment of the multi-speed transmission shown in FIG. 4 a is more easily understood with reference to the stick diagram of FIG. 4 b. The input from the engine drives mounting plate 32 which is fastened to drive shell 28 connected to input hub 34 of disconnect clutch 14. The output side of disconnect clutch 14 is connected to the rotor portion of motor 16, which in turn is attached to rotor shaft 36. Coaxially oriented within rotor shaft 36 is a fixed stator shaft 40 which is mounted to the transmission case, and the transmission input shaft 38. The torque converter impeller I drives torque converter turbine T which is connected to transmission input shaft 38. The torque converter 18 is further provided with a stator S mounted on the stator shaft 40, by way of a one-way clutch 56. In the preferred embodiment illustrated, torque converter 18 is further provided with a lock up clutch 58 which locks the turbine to the impeller in a well known manner.

The gear set of the planetary automatic transmission 20 is made up of three planetary stages; plan 1, plan 2 and plan 3, which are coaxially aligned and axially spaced as shown. Each planetary gear set has a sun, a ring and a series of plant gears supported on a planet carrier. The sun, ring and planet carrier members can be interconnected via a series of five clutches and brakes. For example, in first gear, clutch A and brake D are engaged as illustrated in clutch application table in FIG. 4 c. The transmission input shaft 38 is connected to the ring of planetary gear set Plan 1. The sun is fixed and the planet carrier is connected via clutch A to the sun of planetary gear set 3. With clutch D engaged, the planet carrier of planetary gear set 3 is fixed causing the ring gear of planetary gear set 3 to drive the transmission output shaft 56. In order to shift to the second gear, brake D is released and brake C is simultaneously engaged to cause a change in the transmission gear ratio. Each shift, either up or down, is achieved by releasing one clutch or brake and engaging another. Similarly, the shift from first reverse is done by a single clutch release, a simultaneous engagement of another clutch.

Planetary gear sets 2 and 3 share a common planet element as well as a common ring gear. Planetary gear sets 1 and 2 are traditional, simple planetary gear sets, while planetary gear set 3 is a compound planetary gear set having a pair of inter-meshed planets, one engaging the sun and one engaging the ring. In the embodiment illustrated in FIG. 4 b, the compound planet arrangement enables the third planetary gear set to use a smaller sun and accordingly, obtain a higher gear reduction ratio. Again, the planetary gear set is described merely to illustrate the preferred embodiment, however, the invention can be practiced with a wide variety of automatic transmission structures.

FIG. 5 is a cross-sectional view illustrating an alternative drive shell arrangement 62 which is designed to accommodate a smaller diameter mounting plate 64. Output flange 30 of the engine crank shaft is attached to mounting plate 64 by a series of bolts extending through an array of holes in the mounting plate spaced from the mounting plate center. The outer peripheral edge of mounting plate 64 is provided with a ring gear 66 for cooperation with the pinion gear of the starter motor. Inboard of the periphery of the mounting plate is a series of holes sized to receive threaded fasteners for connecting the drive shell 62 to the mounting plate 64. In the embodiment illustrated, the drive shell 62 is provided with threaded studs 108 which project through an array of holes in the mounting plate 64 to receive nuts to securely affix the drive shell to the mounting plate. Nuts alternatively could be welded to the mounting plate to receive bolts passing through the apertures in the mounting plate. The mounting plate alternatively may also include a dual mass damper (not shown) in order to reduce torque fluctuations.

Unlike a conventional automatic transmission vehicle, the torque converter 18 is not bolted to the engine mounting plate, rather it is free to rotate within the annular cavity defined by the drive shell 62 and mounting plate 64. The rearward end of the drive shell forms a tubular drive shell outlet member 68 which is connected to disconnect clutch input hub 34. Rearward refers to the direction toward the transmission output shaft 56 which would be to the rear of a vehicle in a traditional rear wheel drive front engine vehicle, however, the terms, “rearward” and “forward” are used for simplicity and explanation purposes. They do not necessarily refer to the front and rear of the vehicle as would not be the case if installed transversely in a front wheel drive vehicle. The forward side of the torque converter 18 is free of studs typically used to attach to the mounting plate.

Preferably, the drive shell tubular output hub 68 is provided with an internal spline to axially cooperate with a complimentary external spline on disconnect clutch input hub 34. Disconnect clutch 14 has a series of inter-leaved plates alternatively connected to the input hub 34 and output hub 70. A disconnect hub ring shape piston 72 cooperates within a corresponding cavity formed in the disconnect clutch output hub 70 and is axially shiftable between an extended locked position when the hydraulic signal advancing the disconnect clutch piston 72 is received, and a retracted position when the signal is not present. Affixed to the outer periphery of the disconnect clutch output hub 70 is the rotor R. Disconnect clutch output hub 70 and rotor R are both mounted on and secured to rotor shaft 36. Rotor shaft 36 is provided with external spline sized to cooperate with a complimentary internal spline on the torque converter input hub 74 which drives impeller I. Torque converter 18 is further provided with a stator S mounted on a stator hub 76 and an output turbine T which is connected to turbine output hub 78 via a torsional damper 82 illustrated in FIG. 5. Turbine output hub 78 is provided with an internal spline cooperating with transmission input shaft 38. Stator hub 76 is mounted on stator shaft 40 which is affixed to and extends out of the transmission housing. In the embodiment illustrated, the stator is mounted on a one-way clutch center in a conventional manner.

The torque converter 18 and drive shell 62 together mate with the four different coaxial aligned members in the transmission and slide on and off during installation like a conventional torque converter in an automatic transmission, simply having one additional coaxial member, the tubular output 68 of the drive shell 62. Accordingly, the use of the drive shell takes very little additional axial space in the motor/transmission assembly. The addition of the disconnect clutch 14 and motor 16 to the transmission, however, does take some additional axial space inside of the transmission housing. As shown in FIG. 6, the motor is oriented coaxially with the disconnect clutch mounted inside of motor rotor R. Motor stator S is securely affixed to the transmission housing by a series of annularly spaced apart bolts which extend through the stator laminate stack. The motor rotor R is mounted to the outer periphery of the disconnect clutch output hub 70 supported on rotor shaft 36.

The rotor shaft 36 is radially located by a roller bearing 80 interposed between the rotor shaft 36 and disconnect input clutch hub 34. The outside diameter of the disconnect clutch input hub is supported upon a wall 48 in the transmission housing by way of a bearing 84. Bearing 84 is designed to take an axial load as well as the radially load inserted by the rotor disconnect clutch output hub assembly. A disconnect clutch output hub 70 is further axially constrained by thrust bearings 86 and 88. Additionally, a circumaxial roller bearing 90 is interposed between the disconnect clutch output hub 70 and stator shaft 40 to axially locate rotor shaft 36 and the associated disconnect clutch and rotor.

The disconnect clutch output hub 70 is provided with internal coolant passageways 92 which feed transmission fluid through the disconnect clutch output hub into the rotor R. As fluid passes through and exits the rotating rotor R, it strikes the windings of stator S to remove excess heat from stator windings and the associated stator laminate stack. As illustrated in FIG. 6, disconnect clutch output hub 70 is also provided with an output spline 94 for driving pump P.

Since the torque converter 18 is no longer affixed to the engine mounting plate, it is necessary to axially and radially constrain the torque converter. The torque converter 18 is pivotally supported on the engine mounting plates 32 and 64 in FIGS. 3 and 5. The engine mounting plates 32, 64 are provided with an axially mounted first bearing member 96 which cooperates with a mating second bearing member on the torque converter 18. As illustrated in FIG. 7, the first bearing member in the preferred embodiment is provided by a roller bearing 96 supported in a bearing cup 98 affixed to the mounting plate on the transmission centerline. The corresponding second bearing member is provided by a stub shaft 100 which is affixed to the shell of torque converter 18. The stub shaft provides radial support for the torque converter while bearing 96 further provides an axial stop for the torque converter in the forward direction. To limit rearward movement of the torque converter, the torque converter is provided with a thrust bearing 102 on the axial center line of the shell interior facing rearward for engaging the end region of the transmission input shaft 38. Of course, alternative structures can be utilized such as placing the stub shaft on the mounting plate and the roller bearing on the torque converter shell.

The motor/transmission assembly 26, as previously described, uses a number of subcomponents which are independently novel. FIG. 8 is a perspective view of the mounting plate 64 formed of a circular disc provided with a centrally axially aligned first bearing member, roller bearing 96, mounted in bearing cup 98. The disc is provided with two circular arrays of mounting holes, an array adjacent the center to attach to the crankshaft of the engine and an array adjacent the periphery to attach to the drive shell 28.

Torque converter 18, illustrated in FIG. 9, is similarly novel. The torque converter outer shell is not provided with the conventional mounting studs, rather it is provided with a central axial second bearing member, which in this case is provided by a stub shaft 100. Other axial central bearing members could alternatively be used provided that they cooperate with a corresponding bearing structure on the mounting plate to bear radial loads and provide a positive forward stop for torque converter movement. The torque converter has an annular rearward facing tubular outlet hub 68 which connects to rotor shaft 36, and a rearward facing thrust bearing 102 on the centerline inside of the shell as show in FIG. 7 to abut the end of transmission input shaft 38.

FIG. 10 illustrates a perspective view of a drive shell 28. The drive shell is an annular member having an outer peripheral structure sufficiently large to freely surround the torque converter. The forward edge of the drive shell 28 is provided with a series of spaced apart fasteners 104 for cooperation with the mounting plate 32. The rearward end of the drive shell forms a tubular output 68 which preferably has a splined internal diameter for engaging a corresponding spline on the disconnect clutch input hub 34. The spaced apart fasteners 104 illustrated are a series of weld studs, however weld nuts could also be used to cooperate with bolts passed through corresponding apertures in the mounting plate.

FIG. 11 illustrates an alternative drive shell embodiment 62 as previously illustrated in FIG. 5. In order to accommodate a small diameter mounting plate and a relatively large torque converter, the drive shell is provided with a series of inwardly projecting radial members 106 supporting fasteners The illustrated fasteners are provided by studs 108 located at the diameter of the array of holes in the mounting plate which is significantly less than the diameter of the torque converter. As a result, the inwardly projecting members 106 entrap the torque converter 18 inside the large annular cavity formed within the drive shell 62 creating the illustrated drive shell torque converter sub assembly.

Referring to FIG. 12, disconnect clutch 14 further includes a blocker ring 110, secured against axial displacement relative to output hub 70; a balance dam 112, also secured against axial displacement relative to output hub 70; a return spring 114, contacting piston 72 and balance dam 112 at opposite ends of the spring; and a sealed hydraulic cylinder 116, in which the piston moves subject to the force of spring 114 and a pressure force. A hydraulic passage 118 carries actuating pressure from an outlet port 120 of a pump housing 122 through an axial passage 123 to the portion of cylinder 116 located behind piston 72. When pressure in passage 118 is high, piston 72 moves axially leftward against the force of spring 114 forcing the friction plates and spacer plates of clutch 14 unto mutually frictional contact, thereby engaging clutch 14.

An axial hydraulic passage 124 carries fluid from pump housing 122 through passage 126 to the portion of cylinder 116 that is located between piston 72 and balance dam 112. Hydraulic passage 124 also carries fluid from pump housing 122 through radial passage 92 to the rotor R and stator S of motor 16. Passage 92 communicates with passages 128, which direct fluid across the width of motor 16 and onto the surfaces of rotor R. Fluid exiting the rotor flows radially outward at opposite axial sides due to centrifugal force and onto the surface of the stator S. This fluid, which carries heat away from the motor 16, flows downward though an opening 129 (shown in FIG. 14) in the housing 42 and returns to the sump 52.

Hydraulic fluid that fills the torque converter 18 is carried from pump P through radial passage 130 and axial passage 132, which is located in an annular space between stator shaft 40 and the transmission input shaft 38. The forward end of passage 132 communicates through a radial passage 134 with the toroidal chamber of the torque converter, which is surrounded by the shroud 136 and contains the impeller I, turbine T and stator S. Hydraulic fluid exiting torque converter 18 is carried through an axial passage 138 formed in the transmission input shaft 38 and extending along axis 140.

As FIG. 12 shows, the motor's stator S is secured by a series of bolts 150 to the transmission case 42, which is formed with an opening 152. Each bolt 150 passes though a hole formed in the stator S, and the threaded shank of each bolt engages a threaded hole formed in the casing 42. Close dimensional tolerances are established among the lower surface 153 of stator S, the centerline through the hole in stator S and bolts 150, and the location of axis 140. In this way the distance between axis 140 and the lower surface 153 of stator S is established within a close dimensional tolerance in order to establish and maintain a narrow air gap between the motor's stator S and rotor R.

A terminal assembly 154, seated on a mounting surface 156 that surrounds the opening 152, includes a block 157 that contains electric terminals 158 including at least one high voltage terminal that is electrically connected to the windings within laminates 160 of the motor's stator S. Each terminal 158 is connected by a bolt 162, whose shank passes through a plate 164, which is secured by bolts 166 to the transmission case 42. Each bolt 162 also electrically connects and secures each terminal 158 to a receptacle 168, which engages a conductor 170 connected to the stator S. Both receptacle 168 and conductor are elastically flexible in flexure such that their connection to stator S is completed and maintained without substantially altering the distance between surface 153 and axis 140.

The terminal block assembly 154 is preferably located at an angular location relative to axis 140 that places the terminals 158 at a lateral side of the transmission case 42, rather than at the higher elevation shown in FIG. 12. Preferably the terminals 158 are directed along axis 140, although not necessarily parallel to the axis, and the receptacles of the terminals face rearward, as FIG. 13 shows.

The rotor R of motor 16 is secured to output hub 70 such that an air gap located between the stator's reference surface 153 and the radial outer surface 176 of the rotor is established.

As FIG. 14 shows housing 44 is secured by a series of bolts 177 to the transmission housing 42. The pump's centering plate P is guided into its correct position, both radial and axial, due to contact between surface 178 on the pump's centering plate P and a pilot surface 180 on the transmission housing 42. Similarly pump housing 122 is guide into its correct position, due to contact between surface 182 on the pump centering plate P and a surface 184 on the pump housing 122. At the rearward end, the outer surface of stator shaft 40 contacts the radial inner surface of pump centering plate P, and at the forward end the outer surface of stator shaft 40 contacts the radial inner surface of the torque converter input hub 74.

The axial and radial location of bearing 84 is established by its contact with the rear wall 48 of housing 44. The axial and radial location of clutch input hub 34 is established by its contact with bearing 84. The position of the forward end of rotor shaft 36 is established by its contact with roller bearing 80, and the position of the rearward end of rotor shaft 36 is established by its contact with the inner surface of pump housing 122.

The position of the forward end of output hub 70 and rotor R is established by contact between the outer surface of rotor shaft 36 and the inner surface of output hub 70. The axial and radial location of bearing 190 is established by its contact with the pump housing 122. The position of the rearward end of output hub 70 and rotor R are established by contact between bearing 190 and the output hub 70.

In this way the radial position of the radial outer surface 176 of the rotor R of motor 16 is located such that the air gap parallel to a radius extending from axis 140 and located between the stator's reference surface 153 and the radial outer surface 176 of the rotor is preferably about 122 mm.

FIG. 15 shows a torsion damper 196 located in a power path between the engine 12 and the drive shell 28, 62. Engine 12 is connected through crankshaft flange 30 to an input of damper 196, and a series of bolts 108, spaced mutually around axis 140, connect the output of damper 196 to drive shell 28, 62. Damper 196 attenuates torsional vibrations produced by the engine. The outer peripheral edge of damper 196 is provided with a ring gear 66, which is engaged by a pinion gear driven in rotation by a starter motor.

FIG. 15 shows damper 196 arranged in series with damper 82 between engine 12 and transmission input shaft 38. The presence of damper 196 in the powertrain may eliminate need for torsion damper 82, which is located in a torque delivery path of torque converter 18 between the impeller shroud 136 and the turbine hub 78. When damper 82 is eliminated, the axial dimension of the torque converter 18 and drive shell 28, 62 can be reduced.

As required, detailed embodiments of the present invention are disclosed herein; however, it is to be understood that the disclosed embodiments are merely exemplary of the invention that may be embodied in various and alternative forms. The figures are not necessarily to scale; some features may be exaggerated or minimized to show details of particular components. Therefore, specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a representative basis for teaching one skilled in the art to variously employ the present invention.

While exemplary embodiments are described above, it is not intended that these embodiments describe all possible forms of the invention. Rather, the words used in the specification are words of description rather than limitation, and it is understood that various changes may be made without departing from the spirit and scope of the invention. Additionally, the features of various implementing embodiments may be combined to form further embodiments of the invention. 

What is claimed is:
 1. A hydraulic circuit for a vehicle powertrain, comprising: a first line for carrying fluid to a torque converter; a second line for carrying fluid from the torque converter; a third line for carrying fluid to a balance dam and an electric motor; a fourth line for supplying actuating pressure to a clutch, said lines being coaxial.
 2. The hydraulic circuit of claim 1, further comprising: a transmission input shaft; a stator shaft connected to a stator of the torque converter, wherein the first line is located in an annular space between the transmission input shaft and the stator shaft.
 3. The hydraulic circuit of claim 1, wherein the second line is located in a transmission input shaft.
 4. The hydraulic circuit of claim 1, further comprising: an input hub of an impeller of the torque converter; a rotor shaft driveably connected to said input hub; an output hub connected to the clutch and electric motor; and wherein the third line is located in an annular space between the rotor shaft and the output hub.
 5. The hydraulic circuit of claim 1, further comprising: an input hub of an impeller of the torque converter; a rotor shaft driveably connected to said input hub; an output hub connected to the clutch and electric motor; and wherein the fourth line is located in an annular space between the rotor shaft and the output hub.
 6. The hydraulic circuit of claim 1, further comprising: a pump; a sump for containing fluid supplied to the pump, and fluid that exits the electric motor.
 7. The hydraulic circuit of claim 1, wherein said lines are mutually concentric and aligned with an axis.
 8. A hydraulic circuit for a vehicle powertrain, comprising: a housing enclosing a wet chamber containing a clutch and a motor; a second housing enclosing a dry chamber containing a torque converter; a first line for carrying fluid to the torque converter; a second line for carrying fluid from the torque converter; a third line for carrying fluid to a balance dam and the motor; a fourth line for supplying pressure to the clutch.
 9. The hydraulic circuit of claim 8, further comprising: a transmission input shaft; a stator shaft connected to a stator of the torque converter, wherein the first line is located in an annular space between the transmission input shaft and the stator shaft and extends between the wet and dry chambers.
 10. The hydraulic circuit of claim 8, wherein the second line is located in a transmission input shaft that extends between the wet and dry chambers.
 11. The hydraulic circuit of claim 8, further comprising: an input hub of an impeller of the torque converter; a rotor shaft driveably connected to said input hub; an output hub connected to the clutch and electric motor; and wherein the third line is located in an annular space between the rotor shaft and the output hub.
 12. The hydraulic circuit of claim 8, further comprising: an input hub of an impeller of the torque converter; a rotor shaft driveably connected to said input hub; an output hub connected to the clutch and electric motor; and wherein the fourth line is located in an annular space between the rotor shaft and the output hub.
 13. The hydraulic circuit of claim 8, further comprising: a pump located in the wet chamber, the clutch and motor located axially between the torque converter and the pump; and a sump located in the wet chamber for containing fluid supplied to the pump and fluid that exits the motor.
 14. The hydraulic circuit of claim 8, wherein said lines are mutually concentric and aligned with an axis.
 15. A hydraulic circuit for a vehicle powertrain, comprising: a clutch; a motor radially aligned with and located radially outward of the motor; a torque converter; a first line for carrying fluid to the torque converter; a second line for carrying fluid from the torque converter; a third line for carrying fluid axially and radially to a balance dam and the motor; a fourth line directed axially and radially for supplying pressure to the clutch.
 16. The hydraulic circuit of claim 15, further comprising: a transmission input shaft; a stator shaft connected to a stator of the torque converter, wherein the first line is located in an annular space between the transmission input shaft and the stator shaft.
 17. The hydraulic circuit of claim 15, wherein the second line is located in a transmission input shaft.
 18. The hydraulic circuit of claim 15, further comprising: an input hub of an impeller of the torque converter; a rotor shaft driveably connected to said input hub; an output hub connected to the clutch and electric motor; and wherein a first portion of the third line extends axially in an annular space between the rotor shaft and the output hub, and a second portion is directed radially outward from the first portion to the balance dam.
 19. The hydraulic circuit of claim 18, wherein a third portion of the third line is directed radially outward from the first portion to the motor.
 20. The hydraulic circuit of claim 15, further comprising: an input hub of an impeller of the torque converter; a rotor shaft driveably connected to said input hub; an output hub connected to the clutch and electric motor; and wherein the fourth line is located in an annular space between the rotor shaft and the output hub. 